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Influence Vectors Control for Robots Using Cellular-like Binary Actuators

Robotics 2024-07-26 v1

Abstract

Robots using cellular-like redundant binary actuators could outmatch electric-gearmotor robotic systems in terms of reliability, force-to-weight ratio and cost. This paper presents a robust fault tolerant control scheme that is designed to meet the control challenges encountered by such robots, i.e., discrete actuator inputs, complex system modeling and cross-coupling between actuators. In the proposed scheme, a desired vectorial system output, such as a position or a force, is commanded by recruiting actuators based on their influence vectors on the output. No analytical model of the system is needed; influence vectors are identified experimentally by sequentially activating each actuator. For position control tasks, the controller uses a probabilistic approach and a genetic algorithm to determine an optimal combination of actuators to recruit. For motion control tasks, the controller uses a sliding mode approach and independent recruiting decision for each actuator. Experimental results on a four degrees of freedom binary manipulator with twenty actuators confirm the method's effectiveness, and its ability to tolerate massive perturbations and numerous actuator failures.

Keywords

Cite

@article{arxiv.2407.18140,
  title  = {Influence Vectors Control for Robots Using Cellular-like Binary Actuators},
  author = {Alexandre Girard and Jean-Sébastien Plante},
  journal= {arXiv preprint arXiv:2407.18140},
  year   = {2024}
}
R2 v1 2026-06-28T17:53:40.256Z